DocumentCode
841025
Title
Median power and median correlation theory
Author
Arce, Gonzalo R. ; Li, Yinbo
Author_Institution
Dept. of Electr. & Comput. Eng., Delaware Univ., Newark, DE, USA
Volume
50
Issue
11
fYear
2002
fDate
11/1/2002 12:00:00 AM
Firstpage
2768
Lastpage
2776
Abstract
We show that the maximum likelihood (ML) estimate of location under the Laplacian model, which forms the basis for weighted median filters, can be generalized to correlation estimates based on weighted medians. Much like linear sample correlations, the resultant median correlation estimates have a surprisingly simple structure. Unlike linear correlations, median correlations are robust to data contamination. Notably, weights in this framework do not assume fixed values as with weighted median filters but take on random values determined by the underlying data itself. The underlying parameters associated with the sample median correlations are obtained, leading to well-defined expressions that can be used in subspace-based signal processing algorithms. The properties of median correlations are illustrated through a number of simulations where the MUltiple SIgnal Classification (MUSIC) algorithm is applied on linear and median sample correlation matrices for real-valued frequency estimation applications. This paper thus unveils new and powerful capabilities of weighted medians for use in modern signal processing applications.
Keywords
correlation theory; filtering theory; frequency estimation; impulse noise; matrix algebra; maximum likelihood estimation; median filters; signal classification; Laplacian model; ML estimate; MUSIC algorithm; MUSIC algorithms; data contamination robustness; linear sample correlation matrix; linear sample correlations; maximum likelihood estimate; median correlation estimates; median correlation theory; median power; median sample correlation matrix; multiple signal classification; random values; real-valued frequency estimation; simulations; subspace-based signal processing algorithms; weighted median filters; Filters; Frequency estimation; Laplace equations; Maximum likelihood estimation; Multiple signal classification; Probability distribution; Random variables; Robustness; Signal processing; Signal processing algorithms;
fLanguage
English
Journal_Title
Signal Processing, IEEE Transactions on
Publisher
ieee
ISSN
1053-587X
Type
jour
DOI
10.1109/TSP.2002.804092
Filename
1041034
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